/** * Copyright 2019-2020 Huawei Technologies Co., Ltd * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "graph/passes/folding_kernel/maximum_kernel.h" #include #include #include "common/debug/log.h" #include "common/fp16_t.h" #include "common/types.h" #include "common/util.h" #include "framework/common/debug/ge_log.h" #include "framework/common/ge_inner_error_codes.h" #include "graph/common/bcast.h" #include "graph/utils/type_utils.h" #include "inc/kernel_factory.h" namespace ge { namespace { const size_t kMaximumInputNum = 2; const size_t kMaximumFirstInput = 0; const size_t kMaximumSecondInput = 1; const size_t kMaximumFirstOutput = 0; const std::set kMaximumSupportedType = {DT_FLOAT, DT_FLOAT16, DT_INT8, DT_INT16, DT_UINT16, DT_UINT8, DT_INT32, DT_INT64, DT_UINT32, DT_UINT64, DT_DOUBLE}; #define DEFINE_FUNC_BY_TYPE(TYPE) \ std::function func_##TYPE = [](TYPE const &a, TYPE const &b) -> TYPE { \ return (a > b ? a : b); \ }; #define SET_BCAST_COMPUTE_CASE(DTYPE, TYPE) \ case DTYPE: \ ret = bcast.BCastCompute(input, y_data_##TYPE, func_##TYPE); \ break; #define SET_OUTPUT(DTYPE, TYPE) \ case DTYPE: \ if (output_ptr->SetData(reinterpret_cast(y_data_##TYPE.data()), y_data_##TYPE.size() * length) != \ GRAPH_SUCCESS) { \ GELOGW("GenData: SetData failed"); \ } \ break; DEFINE_FUNC_BY_TYPE(int8_t) DEFINE_FUNC_BY_TYPE(int16_t) DEFINE_FUNC_BY_TYPE(int32_t) DEFINE_FUNC_BY_TYPE(int64_t) DEFINE_FUNC_BY_TYPE(uint8_t) DEFINE_FUNC_BY_TYPE(uint16_t) DEFINE_FUNC_BY_TYPE(uint32_t) DEFINE_FUNC_BY_TYPE(uint64_t) DEFINE_FUNC_BY_TYPE(fp16_t) DEFINE_FUNC_BY_TYPE(float) DEFINE_FUNC_BY_TYPE(double) } // namespace Status MaximumKernel::Compute(const OpDescPtr op_desc_ptr, const std::vector &input, std::vector &v_output) { GELOGD("MaximumKernel in"); if (op_desc_ptr == nullptr) { GELOGE(PARAM_INVALID, "Parameter's invalid, input opDescPtr is nullptr."); return PARAM_INVALID; } Status ret = MaximumCheck(input); if (ret != SUCCESS) { return ret; } std::vector y_data_int8_t; std::vector y_data_int16_t; std::vector y_data_int32_t; std::vector y_data_int64_t; std::vector y_data_uint8_t; std::vector y_data_uint16_t; std::vector y_data_uint32_t; std::vector y_data_uint64_t; std::vector y_data_fp16_t; std::vector y_data_float; std::vector y_data_double; if (input.empty()) { GELOGE(FAILED, "input is empty."); return FAILED; } DataType data_type = input[kMaximumFirstInput]->GetTensorDesc().GetDataType(); BCast bcast; switch (data_type) { SET_BCAST_COMPUTE_CASE(DT_INT8, int8_t) SET_BCAST_COMPUTE_CASE(DT_INT16, int16_t) SET_BCAST_COMPUTE_CASE(DT_INT32, int32_t) SET_BCAST_COMPUTE_CASE(DT_INT64, int64_t) SET_BCAST_COMPUTE_CASE(DT_UINT8, uint8_t) SET_BCAST_COMPUTE_CASE(DT_UINT16, uint16_t) SET_BCAST_COMPUTE_CASE(DT_UINT32, uint32_t) SET_BCAST_COMPUTE_CASE(DT_UINT64, uint64_t) SET_BCAST_COMPUTE_CASE(DT_FLOAT16, fp16_t) SET_BCAST_COMPUTE_CASE(DT_FLOAT, float) SET_BCAST_COMPUTE_CASE(DT_DOUBLE, double) default: ret = NOT_CHANGED; break; } if (ret != SUCCESS) { GELOGW("BCastCompute fail, data_type: %s, ret: %s", TypeUtils::DataTypeToSerialString(data_type).c_str(), GET_ERRORNO_STR(ret).c_str()); return NOT_CHANGED; } uint32_t length = 1; if (!TypeUtils::GetDataTypeLength(data_type, length)) { GELOGW("Can't GetDataTypeLength of data_type: %s", TypeUtils::DataTypeToSerialString(data_type).c_str()); return NOT_CHANGED; } GeTensorPtr output_ptr = MakeShared(op_desc_ptr->GetOutputDesc(kMaximumFirstOutput)); if (output_ptr == nullptr) { GELOGE(MEMALLOC_FAILED, "Make shared failed"); return MEMALLOC_FAILED; } output_ptr->MutableTensorDesc().SetShape(GeShape(bcast.GetOutputShape())); // only return GRAPH_SUCCESS here switch (data_type) { SET_OUTPUT(DT_INT8, int8_t) SET_OUTPUT(DT_INT16, int16_t) SET_OUTPUT(DT_INT32, int32_t) SET_OUTPUT(DT_INT64, int64_t) SET_OUTPUT(DT_UINT8, uint8_t) SET_OUTPUT(DT_UINT16, uint16_t) SET_OUTPUT(DT_UINT32, uint32_t) SET_OUTPUT(DT_UINT64, uint64_t) SET_OUTPUT(DT_FLOAT16, fp16_t) SET_OUTPUT(DT_FLOAT, float) SET_OUTPUT(DT_DOUBLE, double) default: break; } output_ptr->MutableTensorDesc().SetDataType(data_type); v_output.push_back(output_ptr); GELOGD("MaximumKernel success"); return SUCCESS; } Status MaximumKernel::MaximumCheck(const std::vector &input) { // check input number if (input.size() != kMaximumInputNum) { GELOGI("The number of input for Maximum must be %zu.", kMaximumInputNum); return NOT_CHANGED; } ConstGeTensorPtr input_x1 = input.at(kMaximumFirstInput); ConstGeTensorPtr input_x2 = input.at(kMaximumSecondInput); GE_CHECK_NOTNULL(input_x2); GE_CHECK_NOTNULL(input_x2); // check whether there is data in Tensor if (input_x1->GetData().size() == 0 || input_x2->GetData().size() == 0) { GELOGI("Check data size fail. x1: %zu, x2: %zu", input_x1->GetData().size(), input_x2->GetData().size()); return NOT_CHANGED; } // check whether the data types are the same DataType type = input_x1->GetTensorDesc().GetDataType(); if (type != input_x2->GetTensorDesc().GetDataType()) { GELOGI("Data type of inputs for Maximum not matched."); return NOT_CHANGED; } // check if input data type is supported if (kMaximumSupportedType.find(type) == kMaximumSupportedType.end()) { GELOGI("Maximum does not support this Data type: %s", TypeUtils::DataTypeToSerialString(type).c_str()); return NOT_CHANGED; } return SUCCESS; } REGISTER_KERNEL(MAXIMUM, MaximumKernel); } // namespace ge